BackgroundThe efficacy of the 8-aminoquinoline (8AQ) drug primaquine (PQ) has been historically linked to CYP-mediated metabolism. Although to date no clear evidence exists in the literature that unambiguously assigns the metabolic pathway or specific metabolites necessary for activity, recent literature suggests a role for CYP 2D6 in the generation of redox active metabolites.MethodsIn the present study, the specific CYP 2D6 inhibitor paroxetine was used to assess its effects on the production of specific phenolic metabolites thought to be involved in PQ efficacy. Further, PQ causal prophylactic (developing liver stage) efficacy against Plasmodium berghei in CYP 2D knockout mice was assessed in comparison with a normal C57 background and with humanized CYP 2D6 mice to determine the direct effects of CYP 2D6 metabolism on PQ activity.ResultsPQ exhibited no activity at 20 or 40 mg/kg in CYP 2D knockout mice, compared to 5/5 cures in normal mice at 20 mg/kg. The activity against developing liver stages was partially restored in humanized CYP 2D6 mice.ConclusionsThese results unambiguously demonstrate that metabolism of PQ by CYP 2D6 is essential for anti-malarial causal prophylaxis efficacy.
Lactacystin (structure 1 in Fig. 1) is a Streptomyces metabolite that inhibits cell proliferation and induces neurite outgrowth in the mouse neuroblastoma cell line Neuro 2A (1, 2). Cells induced to differentiate by treatment with lactacystin display a predominantly bipolar (two-neurite-bearing) morphology, particularly between 16 and 32 h after treatment, and become more multipolar (multiple-neurite-bearing) upon continued exposure, with increased branching of neurites. In contrast, serum deprivation or treatment of Neuro 2A cells with agents that increase intracellular cAMP levels tends to induce a predominantly multipolar type of neurite outgrowth (3, 4), whereas treatment with agents such as retinoic acid, natural gangliosides, and synthetic sialyl compounds tends to result in a predominantly unipolar (single-neurite-bearing) type of neurite outgrowth in the population of differentiated cells (3, 4).Mature neurons exhibit a variety ofphenotypes in terms of both morphology and physiology. In vertebrate development, neuroblasts from the neural tube and neural crest differentiate into specialized neurons with uni-, bi-or multipolar morphology depending on developmental history (5). The molecular mechanisms underlying these cell-fate determinations remain to be fully elucidated. Lactacystin may prove to be a useful reagent for studying the signal transduction pathways involved in neuronal differentiation and the induction of bipolar morphology. MATERIALS AND METHODSMaterials. Lactacystin used in the biological assays was provided by S. 'Omura of the Kitasato Institute. Lactacystin analogs were synthesized by methods reported elsewhere (6-9). The structure of clasto-lactacystin 3-lactone (structure 4 in Fig. 1 3358The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact.
BackgroundThe 8-aminoquinoline (8AQ) drug primaquine (PQ) is currently the only approved drug effective against the persistent liver stage of the hypnozoite forming strains Plasmodium vivax and Plasmodium ovale as well as Stage V gametocytes of Plasmodium falciparum. To date, several groups have investigated the toxicity observed in the 8AQ class, however, exact mechanisms and/or metabolic species responsible for PQ’s haemotoxic and anti-malarial properties are not fully understood.MethodsIn the present study, the metabolism of PQ was evaluated using in vitro recombinant metabolic enzymes from the cytochrome P450 (CYP) and mono-amine oxidase (MAO) families. Based on this information, metabolite identification experiments were performed using nominal and accurate mass measurements.ResultsRelative activity factor (RAF)-weighted intrinsic clearance values show the relative role of each enzyme to be MAO-A, 2C19, 3A4, and 2D6, with 76.1, 17.0, 5.2, and 1.7% contributions to PQ metabolism, respectively. CYP 2D6 was shown to produce at least six different oxidative metabolites along with demethylations, while MAO-A products derived from the PQ aldehyde, a pre-cursor to carboxy PQ. CYPs 2C19 and 3A4 produced only trace levels of hydroxylated species.ConclusionsAs a result of this work, CYP 2D6 and MAO-A have been implicated as the key enzymes associated with PQ metabolism, and metabolites previously identified as potentially playing a role in efficacy and haemolytic toxicity have been attributed to production via CYP 2D6 mediated pathways.
Primaquine is the only antimalarial drug available to clinicians for the treatment of relapsing forms of malaria. Primaquine development and usage dates back to the 1940s and has been administered to millions of individuals to treat and eliminate malaria infections. Primaquine therapy is not without disadvantages, however, as it can cause life threatening hemolysis in humans with glucose-6-phosphate dehydrogenase (G6PD) deficiency. In addition, the efficacy of primaquine against relapsing malaria was recently linked to CYP 2D6 mediated activation to an active metabolite, the structure of which has escaped definitive identification for over 75years. CYP 2D6 is highly polymorphic among various human populations adding further complexity to a comprehensive understanding of primaquine pharmacology. This review aims to discuss primaquine pharmacology in the context of state of the art understanding of CYP 2D6 mediated 8-aminoquinoline metabolic activation, and shed light on the current knowledge gaps of 8-aminoquinoline mechanistic understanding against relapsing malaria.
Primaquine (PQ) metabolism by the cytochrome P450 (CYP) 2D family of enzymes is required for antimalarial activity in both humans (2D6) and mice (2D). Human CYP 2D6 is highly polymorphic, and decreased CYP 2D6 enzyme activity has been linked to decreased PQ antimalarial activity. Despite the importance of CYP 2D metabolism in PQ efficacy, the exact role that these enzymes play in PQ metabolism and pharmacokinetics has not been extensively studied in vivo. In this study, a series of PQ pharmacokinetic experiments were conducted in mice with differential CYP 2D metabolism characteristics, including wild-type (WT), CYP 2D knockout (KO), and humanized CYP 2D6 (KO/knock-in [KO/KI]) mice. Plasma and liver pharmacokinetic profiles from a single PQ dose (20 mg/kg of body weight) differed significantly among the strains for PQ and carboxy-PQ. Additionally, due to the suspected role of phenolic metabolites in PQ efficacy, these were probed using reference standards. Levels of phenolic metabolites were highest in mice capable of metabolizing CYP 2D6 substrates (WT and KO/KI 2D6 mice). PQ phenolic metabolites were present in different quantities in the two strains, illustrating species-specific differences in PQ metabolism between the human and mouse enzymes. Taking the data together, this report furthers understanding of PQ pharmacokinetics in the context of differential CYP 2D metabolism and has important implications for PQ administration in humans with different levels of CYP 2D6 enzyme activity. P rimaquine (PQ) is the only FDA-approved drug for treatment of relapsing infections with malarial strains, including Plasmodium vivax and P. ovale (1-3). PQ belongs to the 8-aminoquinoline (8AQ) class of antimalarial compounds, among which several molecules, including PQ, have potent antihypnozoite activity (2, 4, 5). Low doses of PQ are also recommended for malaria transmission-blocking efforts due to PQ's gametocidal activity (6, 7). PQ's utility in malaria treatment and potential use in malarial transmission reduction and malaria eradication efforts require an understanding of the molecular species involved in its mechanism of action.Recent reports have shown that PQ requires metabolic activation by the cytochrome P450 (CYP) 2D isoenzymes for liver-stage antimalarial activity in both mouse studies (CYP 2D) and human studies (CYP 2D6) (8-11). Pybus et al. demonstrated that PQ was active only in mice capable of metabolizing CYP 2D6 substrates. Deletion of the mouse enzyme closest to human CYP 2D6 (mouse CYP 2D22 via deletion of the CYP 2D gene cluster) in mice completely blocked liver-stage antimalarial activity in vivo (10). The study by Bennett et al. demonstrated a direct link between CYP 2D6 metabolizer status and PQ efficacy for P. vivax treatment in several human subjects (8). PQ therapy is of significant importance for P. vivax radical cure, presumptive antirelapse therapy (PART), and malaria eradication efforts, and the requirement of CYP 2D6 metabolism for PQ efficacy is problematic because CYP 2D6 is highly polymorp...
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